GARDEN WATERING CONTROLLERS

Abstract

A garden watering controller for operating a valve for controlling supply of water into a garden watering arrangement, includes wireless receiver means for wirelessly receiving programming data signals, and a central unit for outputting control signals for operating the valve in dependence on the received programming data signals.

Description

This invention relates to garden watering controllers and garden watering controller units (also known as water computers) as well as to methods and apparatus for controlling garden watering controllers.

Garden watering controller units are used for controlling home watering arrangements such as micro-irrigation systems by turning the water supply on to allow watering at preselected times or under preselected conditions.

Typically, a garden watering controller unit is mountable on an outside tap which is left in an “on” position whereas the garden watering controller unit controls whether water is actually able to enter the garden watering arrangement via a hose connected to an outlet of the garden watering controller unit.

Some garden watering controller units offer only very simple timer based operation and may, for example, be programmable to water for 30 minutes at a time specified by an internal clock. Other units may be more complex and have a screen based programmable functionality, similar to say a central heating control, such that various “on” and “off” times may be set and these might be set to occur every day or only on certain pre-programmed days.

A difficulty with these systems is that they are complex and time consuming to programme and the user interfaces, displays and so on may be fiddly to use. Furthermore, there is no easy way to change the behaviour of the unit if the situation should change. Further, such units do not necessarily lead to watering at optimum times with reference to the different number of daylight hours as one moves through the year or in different weather conditions. A user, for example, might prefer to have watering occur at dusk every day but on a time based programmable system this would only be possible if the programmed time of watering was altered on a regular basis. Similarly, the user may wish to alter watering behaviour as weather changes but again with a time based programmable system this is only possible by altering the programmed time on a regular basis.

It would be desirable to have a garden watering controlling unit which facilitates ease of use whilst also allowing better functionality for the user.

According to a first aspect of the present invention there is provided a garden watering controller for operating a valve for controlling supply of water into a garden watering arrangement, the controller comprising wireless receiver means for wirelessly receiving programming data signals, and a central unit for outputting control signals for operating the valve in dependence on the received programming data signals.

According to a second aspect of the present invention there is provided a tap mountable garden watering controller unit comprising a valve for controlling supply of water from a tap into a garden watering arrangement, and a garden watering controller as defined above for operating the valve.

These arrangements allow for the remote control of the watering controller and hence of watering. Ultimately control may be provided via a network, such as a LAN and/or the internet.

Typically the garden watering controller and controller unit will be battery powered.

Typically the valve will be an electrically operated valve, for example a motor driven valve or a solenoid valve.

The central unit may be arranged to store a watering schedule received via the programming data signals and arranged to operate the valve in dependence on the stored watering schedule.

This facilitates operation of the watering controller and hence the valve without the need for continual wireless communication. This can be helpful since it can help reduce battery consumption.

The controller may be arranged under the control of software to have a sleep mode in which the controller does not conduct wireless communication and a wireless communication mode in which the controller looks for programming data signals.

The controller may be arranged to enter the wireless communication mode periodically with a respective wakeup interval between each entry into the wireless communication mode.

The length of the wakeup interval may be varied in dependence on predetermined conditions.

These features are aimed at minimising battery consumption.

The length of the wakeup interval may be increased if battery life is running low. The controller may be arranged to output an indicator signal if battery life is running low. This may in turn facilitate a user choosing a longer wakeup interval. Alternatively the wakeup interval may be increased automatically.

The controller may be arranged to decrease the length of the wakeup interval in dependence on respective predetermined conditions. The respective predetermined condition may comprise situations when it is determined that changes in schedule are likely to be made by the user.

The controller may comprise a manual override control that operates the valve to allow immediate watering. The manual override control may allow selection of a defined period of watering. The manual override control may be a button. The button may be arranged so that subsequent presses of the button cause cycling through an available range of watering durations.

The controller may be arranged to receive user override control signals wirelessly as part of the programming data signals. The user override control signals may be such as to cause immediate watering, or such as to modify a stored schedule. Such modifications may include pausing the programmed schedule so no watering will occur, or adjusting a selected duration of watering specified in the schedule.

The controller may be arranged to decrease the length of the wakeup interval if the user manual override control is used and/or if user override control signals are received, in particular signals which cause immediate watering.

This can allow prompter reaction to deactivation of a water immediately function, or further adjustments to a stored schedule, without permanently increasing battery usage.

The controller may be arranged so that the controller does not engage in wireless communication at the same time as the valve is operated. Again the aim in this is to keep drain on battery power to a minimum.

The controller may store a watering schedule which is dependent on sunrise times and/or sunset times determined in dependence on geo-location data in respect of the garden watering controller.

This can facilitate watering at dawn and/or dusk.

The tap mountable garden watering controller unit may comprise a main body which houses the valve and its respective drive, such as a motor. The garden watering controller may be detachably mountable on the main body.

According to a third aspect of the present invention there is provided a garden watering controller arrangement comprising a garden watering controller as defined above and a hub which is on the one hand connectable to an external network and on the other hand arranged for wireless communication with the garden watering controller.

The garden watering controller arrangement may comprise a tap mountable garden watering controller unit which comprises the garden watering controller and a valve for controlling supply of water from a tap into a garden watering arrangement.

According to a fourth aspect of the present invention there is provided a garden watering controller system comprising:

a garden watering controller as defined above;
a server arranged under the control of software for communication via a network with the garden watering controller;
a client device arranged under the control of software for communication via a network with the server and the garden watering controller and for accepting user inputs which cause control of the garden watering controller.

The garden watering controller system may comprise a hub which is on the one hand connectable to an external network and on the other hand arranged for wireless communication with the garden watering controller.

According to a fifth aspect of the present invention there is provided a client device arranged under the control of software for communication via a network with a garden watering controller as defined above and for accepting user inputs which cause control of the garden watering controller.

According to a sixth aspect of the present invention there is provided a server arranged under the control of software for communication via a network with a garden watering controller as defined above and for communication via a network with a client device which is arranged under the control of software for accepting user inputs which cause control of the garden watering controller.

The client device may be arranged to accept user inputs for generating a watering schedule which is communicated to the garden watering controller and stored therein.

The client device may be arranged to accept user inputs for causing immediate watering by a garden watering controller independently of any water schedule stored therein. The client device may be arranged to accept user inputs for indicating a duration for which immediate watering should take place.

The client device may be arranged to accept user inputs for pausing a watering schedule which is stored in the garden watering controller.

This allows temporary ceasing of watering operation without the need to change the programmed schedule.

The client device may be arranged to accept user inputs for adjusting a watering schedule which is stored in the garden watering controller. The adjustment may comprise altering the duration of watering specified in a stored watering schedule. The client device may be arranged to accept user inputs for adjusting a watering schedule which is stored in the garden watering controller for a selected number of days before the adjustment is removed.

Again this allows temporary modification of watering operation without the need to change the programmed schedule.

The client device may be arranged to indicate to a user if battery life is running low at the garden watering controller.

The client device may be arranged to accept a user input for adjusting the wake up interval of the garden watering controller.

The system, client device, and/or the server may be arranged for determining geo-location data for the garden watering controller. This may be determined from the location of the hub where present. This facilitates various “smart” location based behaviour of the controller.

The geo-location data may be used in controlling operation of the garden watering controller.

The server may be arranged to determine sunrise times and/or sunset times in dependence on the geo-location data.

The client device may be arranged to accept a user input for creating a watering schedule which is dependent on sunrise times and/or sunset times determined in dependence on the geo-location data.

Thus a watering schedule which is dependent on sunrise times and/or sunset times determined in dependence on geo-location data in respect of the garden watering controller may be sent to the garden watering controller.

For example, the user may choose for watering to occur at dawn and/or dusk.

The server may be arranged to acquire weather information in dependence on the geo-location data.

The client device may be arranged to indicate to the user, current weather conditions at the location of the garden watering controller in dependence on the acquired weather information.

The server may be arranged to analyse weather conditions at the determined location of the garden water controller over time and output a weather change indication signal to the client device if predetermined conditions are met by the analysed weather conditions. A weather change indication signal may, for example, be output if the weather has become considerably drier or wetter over the last week or month.

The client device may be arranged to indicate to a user if a weather change indication signal is issued by the server. The user may then decide to increase or decrease watering by modifying or re-programming the stored schedule.

In developments, the system, client device, or server may be arranged to automatically adjust a stored watering schedule at the garden watering controller in response to a weather change indication signal.

According to a seventh aspect of the present invention there is provided a computer program comprising code portions which when loaded and run on a computer cause the computer to operate as a server as defined above, or as a client device as defined above.

According to an eighth aspect of the present invention there is provided a machine readable data carrier, carrying a computer program as defined in the seventh aspect of the present invention.

According to a ninth aspect of the present invention there is provided a method of operating a client device arranged under the control of software for controlling a garden watering controller, comprising the steps of:

communicating via a network with a garden watering controller as defined above;
accepting user inputs at the client device which cause control of the garden watering controller; and
sending programming data signals to the garden watering controller.

According to a tenth aspect of the present invention there is provided a method of operating a server arranged under the control of software for controlling a garden watering controller, comprising the steps of:

communicating via a network with a garden watering controller as defined above; and
sending programming data signals to the garden watering controller; and optionally
communicating via a network with a client device which is arranged under the control of software for accepting user inputs which cause control of the garden watering controller.

According to an eleventh aspect of the invention there is provided a method of operating a garden watering controller including a valve comprising the steps of:

wirelessly receiving programming data signals; and
outputting control signals for operating the valve in dependence on the received data signals.

The optional features mentioned above following the fourth, fifth and sixth aspects of the invention may also form optional feature for use with the methods of the ninth, tenth and eleventh aspects of the invention, with any appropriate changes in wording to render these as method steps. These features are not repeated here merely in the interests of brevity.

According to another aspect of the invention, there is provided a method of determining a watering schedule for use with a garden watering controller comprising the steps of:

acquiring geo-location data representing the location of the controller;
determining the time of sunrise and/or sunset at that location; and
creating the schedule to cause watering at at least one time which depends on the determined sunrise and/or sunset time.

According to a further aspect of the invention there is provided a method for modifying a watering schedule for use with a garden watering controller comprising the steps of:

acquiring geo-location data representing the location of the controller;
acquiring weather observation data for that location;
comparing that data over time; and
adjusting a watering schedule in dependence on the weather observation data and/or said comparison.

Note that in at least some circumstances the garden watering controller may not include a wireless receiver, but rather be provided with a wired connection to a network. Many of the above aspects of the invention will be equally applicable for use with such a wired connected controller. Similarly the above two aspects could be implemented on a stand-alone controller that acquires the geo-location data, weather data, sunrise and/or sunset data directly via a network, wireless or otherwise.

Embodiments of the present invention will now be described, by way of example, only with reference to the accompanying drawings in which:

FIG. 1 schematically shows a garden watering controller unit;

FIG. 2 shows in highly schematic form, the garden watering controller unit of FIG. 1 as part of a garden watering controller system;

FIG. 3 shows an overview of basic operation of the garden watering controller unit of FIGS. 1 and 2;

FIG. 4 is a flowchart illustrating a process for modifying a wake up interval at the garden watering controller unit of FIGS. 1, 2 and 3; and

FIG. 5 schematically shows overall operation of the garden watering controller system of FIG. 2 making use of geo-location data.

FIG. 1 shows a garden watering controller unit 1 in isolation whereas FIG. 2 shows the garden watering controller unit 1 as part of a garden watering controller system. The garden watering controller unit 1 comprises a garden watering controller panel 2 mounted on a main body 3. In the present embodiment, the main body 3 houses a valve unit V comprising a valve 31 and a motor 32 for driving the valve 31. The garden watering controller unit 1 is tap mountable and is shown in FIG. 1 mounted on a tap T via a connector 33 provided on the main body 3. A hose H is shown in FIG. 1 connected to the main body 3 via a respective connector 34.

In terms of basic use of the garden watering controller unit 1, the tap T will be left in an “on” position and the garden watering controller unit 1 controls whether watering occurs. This is by virtue of operating the valve 31 to control whether water is delivered to the hose H and thus onwards into a respective garden watering arrangement be this a simple sprinkler, a micro-irrigation system or so on.

The garden watering control panel 2 comprises a central unit 21 comprising a micro-processor (not shown) and a memory (not shown). The central unit 21 is arranged for overall control of the garden watering controller unit 1 and storing watering schedules. The central unit 21 is connected to a wireless transceiver unit 22 for allowing wireless communication. The garden watering controller unit 1 further comprises one or more battery 23 which may be provided as part of the controller panel 2, the main body 3 or separately from each of these. In the present embodiment, the batteries 23 are carried by the controller panel 2.

Power from the batteries 23 is used for powering the central unit 21, the wireless transceiver unit 22 and the motor 32 which drives the valve 31.

Note that in other embodiments rather than a motor driven valve 31 and motor 32, a solenoid valve may be used or any other appropriate form of electronically controllable valve.

In terms of basic operation, the garden watering controller unit 1 is arranged to control whether the valve 31 is open so as to control watering in dependence on a watering schedule stored at the central unit 21.

The garden watering controller unit 1 also comprises a user operable manual override control 24. In the present embodiment this control 24 is a user operable button which may be used to cause the garden watering controller unit 1 to open the valve 31 and allow immediate watering. If the button is pressed once, watering continues for ten minutes. If the button is pressed twice then watering continues for thirty minutes. If the button is pressed three times then watering is continued for sixty minutes. If the button is pressed again watering stops.

If there is a delay between the first and subsequent presses then the additional time runs from the time of the later press. Thus, say if five minutes of watering have elapsed before the button is pressed for a second time, then that second press will cause an additional thirty minutes of watering. In this way, the manual override button 24 overrides any programmed watering schedules stored in the central unit 21.

As shown in FIG. 2, the garden watering controller system comprises further components in addition to the garden watering controller 1.

In particular, a hub 4 is provided for wirelessly communicating with the garden watering controller unit 1 via the wireless transceiver unit 22. In the present embodiment this wireless communication is 868 MHz two-way radio communication. This particular communication frequency and protocol has been found to be particularly effective in allowing transmission of wireless signals between the garden watering controller unit 1 and the hub 4 where these transmissions need to travel a considerable distance and likely through external walls. This is on the basis that the garden watering controller unit 1 will typically be mounted on an outside tap T as shown in FIG. 1 whereas the hub 4 will normally be located inside the user's property.

The hub 4 is connected via a network N typically the internet, to a server 5 and one or more client devices 6. Each client device may be a mobile device such as a smart phone, a tablet or instead a PC device such as a desktop or a laptop computer.

Software is provided at the server 5 and at each client device 6 enabled for use with the system for allowing control of the operation of the garden watering controller 1. Thus the software at the server and the client devices 6 may be used for sending programming data signals to the garden watering controller unit 1 via the hub 4 so as to store a watering schedule in the central unit 21.

Further, another kind of programming data signals may be sent to the garden watering controlling unit 1. In particular, each client device 6 is arranged (under the control of the provided software) to allow sending of a water immediately override signal from the client device 6 (via the network N and the hub 4) to cause the garden watering controller unit 1 to water immediately in much the same way as pressing the water immediately button 24.

Similarly, each client device 6 is arranged to allow sending of a pause override signal to the garden watering controller unit 1 to pause any watering schedules stored in the central unit 21. Whilst in this pause mode, the garden watering controller unit 1 will not perform any watering. Once the pause instruction is removed by a further operation of a client device 6, the garden watering controller unit 1 will begin to follow the stored watering schedule again.

Moreover, each client device 6 is arranged to allow sending of an adjust override signal to the garden watering controller unit 1 to adjust the operation of a stored watering schedule. The adjust function allows the user to alter the duration for which watering occurs at each selected time in a stored watering schedule.

As will be appreciated, the software provided at each suitably enabled client device 6 may be an “app”.

The above described operation of the system is schematically illustrated in FIG. 3. Thus, in normal circumstances, operation of the valve 31 in the garden watering controller 1 is controlled by a stored watering schedule 301. However, if the water immediately button 24 is operated then this overrides the schedule and causes valve operation 302. Similarly, if the water immediately override is operated from the software provided on a client device 6 (ie the app) at step 303 then this overrides the stored schedule and causes operation of the valve 31. On the other hand if, as in step 304, the pause override control is used from a suitably programmed client device 6, this interrupts and pauses any stored schedule and so ultimately causes control of valve operation. Similarly, if the adjust override function is used 305 at a suitably programmed client device 6, this modifies the stored schedule.

The adjust override functionality discussed in reference to step 305 may be such that the suitably programmed client device 6 allows the user to specify whether a modified level of watering (ie a modified duration of watering) should occur for a specified number of days. Currently, the user may choose between the override operating for between 1 and 14 days before the schedule reverts back to the normal schedule.

Similarly, the override discussed with reference to step 304 may be set to run for a selected period between 1 and 14 days.

With a battery powered wireless device such as the garden watering controller unit 1, battery consumption is a concern. Thus, the garden watering controller panel 2 is arranged to adopt a sleep mode in normal circumstances and when in this sleep mode no wireless communication will take place. The central unit 21 has a normal wake up interval and wakes up the device to look for wireless signals periodically in accordance with this wake up interval.

In the present embodiment, the normal wake up interval is 15 minutes. Thus, in the present embodiment, the garden watering controller unit 1 wakes up every 15 minutes to see if there have been any changes to the watering schedule as currently stored in the central unit 21 and then goes back into sleep mode.

However, there are times when it is desirable to modify this wake up interval and processes in connection with this are illustrated in a flow chart shown in FIG. 4.

In step 401, the garden watering controller panel 2 is a normal state with a normal wake up interval. However if, in step 402, the central unit 21 determines that an override has been activated (be this operation of the water immediately button 24 or one of the client device 6 based overrides) then the wake up interval is decreased in step 403 to provide a more responsive system and this state is retained until the override has been cancelled or the override period is over.

On the other hand if, in step 404, it is determined that the battery level of the battery 23 is low, then it could be desirable to use a longer wake up interval to further preserve battery power. In such a case in the present embodiment the system is arranged so that a notification signal is sent from the garden watering controller unit 1 to the suitably programmed client device 6 to indicate that the battery level is low at step 405. In response to this the user using the client device 6 may send a signal back to the garden watering controller unit 1 to specify a longer wake up interval.

In future developments/alternative embodiments then a longer wake up interval can be automatically selected in response to determination that the battery level is low.

As a further measure to help minimise drain on the battery, the central unit 21 is arranged so that when the battery 23 is being used to power the wireless transceiver unit 22 it is not also used to operate the valve (ie power the motor 32) and vice versa.

The garden watering controller system is also arranged to provide behaviour which is controlled in dependence on geo-location data which can be acquired in respect of the physical location of the garden watering controller unit 1. In particular, in the present embodiment the server 5 is arranged under software to acquire geo-location data from the hub 4 during a set up process. This geo-location data may then be stored in association with the garden watering controller unit 1 and used for various purposes.

FIG. 5 schematically shows processes concerning geo-location data which are used by the garden watering controller system.

In step 501, geo-location data concerning the physical location of the garden watering controller unit 1 is acquired as mentioned above.

In step 502, this acquired information is used to determine sunrise and/or sunset times at the location of the garden watering controller unit 1. Then in step 503, the suitably programmed client device 6 is arranged to allow stored watering schedules to be input by a user based on sunrise and/or sunset times. Thus, the suitably programmed client device 6 allows a user to specify that watering should occur at sunrise, sunset or sunrise and sunset or to put this another way at dawn, at dusk or at dawn and dusk. Based on such inputs from the user and the determined sunrise and sunset times, a suitable watering schedule may be fed to the central unit 21 of the garden watering controller unit 1 in step 504. When this information is sent to the garden watering controller unit 1 in step 504, this may be done every day as sunrise and sunset times change or a batch of scheduling information may be provided in one go to cover operation of the garden watering controller unit 1 for a predefined period, such as a week or so on.

Once geo-location data has been acquired in step 501, the server 5 may also (or alternatively) acquire weather data in step 505 from publically available sources which represent the weather at the location of the garden watering controller unit 1. Correspondingly in step 506, an indication may be given to the user using an appropriately programmed client device 6 of this current weather. For example, the home screen displayed when using an app on the client device 6 may be altered accordingly.

Further, in step 507 the server 5 may acquire weather data over time. Here we are referring to the acquisition of actual observed weather data rather than weather forecast data. Then in step 508, the server 5 and suitably programmed client device 6 may be arranged to issue notifications to a user based on comparisons made in the data collected in step 507. Thus, notifications may be issued to the user in step 508 via the client device 6 if weather has become particularly wetter or particularly drier at the location of the garden watering controller unit 1. Thus, in a specific example, if rainfall over a week has fallen to half a level of rainfall in the previous week, a notification might be issued to a user. The user then could make a decision as to whether to increase the watering provided by the watering arrangement controlled by the garden watering controller unit 1.

Note that in an alternative, or a future development, the system may be arranged (step 509) to automatically adjust a programmed watering schedule stored at the garden watering controller unit 1 in dependence on the weather data acquired in step 505 and/or the analysis conducted in step 507.

The above description has been written in terms of there being a single garden watering controller unit 1. However it will be appreciated that a system may have plural such units 1. In such a case these may all be in communication with one hub and may be individually controllable both locally and over the network N.

Claims

1. A garden watering controller for operating a valve for controlling supply of water into a garden watering arrangement, the controller comprising:

wireless receiver means for wirelessly receiving programming data signals, and

a central unit for outputting control signals for operating the valve in dependence on the received programming data signals.

2. A garden watering controller according to claim 1 in which the central unit is arranged to store a watering schedule received via the programming data signals and arranged to operate the valve in dependence on the stored watering schedule.

3. A garden watering controller according to claim 1 in which the controller is arranged under the control of software to have a sleep mode in which the controller does not conduct wireless communication and a wireless communication mode in which the controller looks for programming data signals, and the controller is arranged to enter the wireless communication mode periodically with a respective wakeup interval between each entry into the wireless communication mode, wherein the length of the wakeup interval is variable in dependence on predetermined conditions.

4. A garden watering controller according to claim 1 in which the controller comprises a manual override control that operates the valve to allow immediate watering.

5. A garden watering controller according to claim 1 in which the controller is arranged to receive user override control signals wirelessly as part of the programming data signals.

6. A garden watering controller according to claim 5 in which the user override control signals are such as to cause immediate watering, or such as to modify a stored schedule.

7. A garden watering controller according to claim 3 in which the controller comprises a manual override control that operates the valve to allow immediate watering and the controller is arranged to decrease the length of the wakeup interval if the user manual override control is used and/or if user override control signals are received.

8. A garden watering controller according to claim 1 in which the controller stores a watering schedule which is dependent on sunrise times and/or sunset times determined in dependence on geo-location data in respect of the garden watering controller.

9. A tap mountable garden watering controller unit comprising a valve for controlling supply of water from a tap into a garden watering arrangement, and a garden watering controller according to claim 1.

10. A garden watering controller system comprising:

a garden watering controller as claimed in claim 1;

a server arranged under the control of software for communication via a network with the garden watering controller;

a client device arranged under the control of software for communication via a network with the server and the garden watering controller and for accepting user inputs which cause control of the garden watering controller.

11. A client device arranged under the control of software for communication via a network with a garden watering controller as claimed in claim 1 and for accepting user inputs which cause control of the garden watering controller.

12. A client device as claimed in claim 11 arranged to accept user inputs for generating a watering schedule which is communicated to the garden watering controller and stored therein.

13. A client device as claimed in claim 11 arranged to accept user inputs for causing immediate watering by a garden watering controller independently of any water schedule stored therein.

14. A client device as claimed in claim 11 arranged to accept a user input for adjusting the wake up interval of the garden watering controller.

15. A client device as claimed in claim 11 arranged to accept a user input for creating a watering schedule which is dependent on sunrise times and/or sunset times determined in dependence on the geo-location data.

16. A client device as claimed in claim 11 arranged to indicate to the user, current weather conditions at the location of the garden watering controller in dependence on acquired weather information.

17. A client device as claimed in claim 11 arranged to indicate to a user if a weather change indication signal is issued in dependence on acquired weather information.

18. A server arranged under the control of software for communication via a network with a garden watering controller as claimed claim 1 and for communication via a network with a client device which is arranged under the control of software for accepting user inputs which cause control of the garden watering controller.

19. A server as claimed in claim 18 arranged to determine sunrise times and/or sunset times in dependence on the geo-location data.

20. A server as claimed in claim 18 arranged to acquire weather information in dependence on the geo-location data.

21. A server as claimed in claim 20 arranged to analyse weather conditions at the determined location of the garden water controller over time and output a weather change indication signal to the client device if predetermined conditions are met by the analysed weather conditions.

22. A machine readable data carrier product carrying a computer program comprising code portions which when loaded and run on a computer cause the computer to operate as a server as claimed in claim 18.

23. A machine readable data carrier product carrying a computer program comprising code portions which when loaded and run on a computer cause the computer to operate as a client device as claimed in claim 11.